Visual acuity in larval zebrafish: behavior and histology

BACKGROUND: Visual acuity, the ability of the visual system to distinguish two separate objects at a given angular distance, is influenced by the optical and neuronal properties of the visual system. Although many factors may contribute, the ultimate limit is photoreceptor spacing. In general, at least one unstimulated photoreceptor flanked by two stimulated ones is needed to perceive two objects as separate. This critical interval is also referred to as the Nyquist frequency and is according to the Shannon sampling theorem the highest spatial frequency where a pattern can be faithfully transmitted. We measured visual acuity in a behavioral experiment and compared the data to the physical limit given by photoreceptor spacing in zebrafish larvae. RESULTS: We determined visual acuity by using the optokinetic response (OKR), reflexive eye movements in response to whole field movements of the visual scene. By altering the spatial frequency we determined the visual acuity at approximately 0.16 cycles/degree (cpd) (minimum separable angle = 3.1 degrees ). On histological sections we measured the retinal magnification factor and the distance between double cones, that are thought to mediate motion perception. These measurements set the physical limit at 0.24 cpd (2.1 degrees ). CONCLUSION: The maximal spatial information as limited by photoreceptor spacing can not be fully utilized in a motion dependent visual behavior, arguing that the larval zebrafish visual system has not matured enough to optimally translate visual information into behavior. Nevertheless behavioral acuity is remarkable close to its maximal value, given the immature state of young zebrafish larvae

Управління трудовим потенціалом при створенні інноваційної продукції

Super-resolution microscopy (SRM) bypasses the diffraction limit, a physical barrier that restricts the optical resolution to roughly 250 nm and was previously thought to be impenetrable. SRM techniques allow the visualization of subcellular organization with unprecedented detail, but also confront biologists with the challenge of selecting the best-suited approach for their particular research question. Here, we provide guidance on how to use SRM techniques advantageously for investigating cellular structures and dynamics to promote new discoveries

Impaired retinal differentiation and maintenance in zebrafish laminin mutants

PURPOSE: To characterize morphologic and physiological alterations in the retina of three laminin mutant zebrafish, bashful (bal, lama1), grumpy (gup, lamb1), and sleepy (sly, lamc1), which were identified in forward genetic screens and were found to be impaired in visual functions. METHODS: Mutant larvae were observed for defects in visual behavior by testing their optokinetic response (OKR). In addition, electroretinograms (ERG) were measured and retinal morphology was examined by standard histology, immunocytochemistry, TUNEL assay, and electron microscopy. RESULTS: Both, gup and sly showed no OKR at any light intensity tested, whereas bal embryos showed some remaining OKR behavior at more than 40% of contrast. Consistent with the OKR result, gup and sly did not show an ERG response at any light intensity tested, whereas bal mutants exhibited small a- and b-waves at high light intensities. All three laminin mutants showed altered ganglion cell layers, optic nerve fasciculations, and lens defects. Again, bal showed the least severe morphologic phenotype with no additional defects. In contrast, both, gup and sly, showed severe photoreceptor outer segment shortening and synapse alteration (floating ribbons) as well as increased cell death. CONCLUSIONS: Lamb1 and lamc1 chains play an important role in the morphogenesis of photoreceptors and their synapses. In contrast, lama1 is not involved in outer retina development

Space-saving advantage of an inverted retina

Vertebrate eyes are of the simple or camera type with a single optical system that creates an image on the retina in the back of the eye. There, the visual information is encoded as nervous signals by photoreceptors, processed by retinal neurons, and then sent to the brain via the optic nerve. Surprisingly at first sight, the retinal neurons are located between the lens and the light-sensitive parts of the photoreceptors. The tissue scatters some light, which leads to loss of light and image blur. The inverted retina has, therefore, long been regarded as inferior. Here, we provide evidence that the inverted retina actually is a superior space-saving solution, especially in small eyes. The inverted retina has most likely facilitated the evolution of image-forming eyes in vertebrates, and it still benefits especially small and highly visual species

A rat model of Parkinsonism shows depletion of dopamine in the retina

The retinal dopamine (DA) deficiency is an important feature of the pathogenesis in Parkinson`s disease (PD) visual dysfunction. Systemic inhibition of complex I (rotenone) in rats has been proposed as a model of PD. In this study, we investigated whether systemic inhibition of complex I can induce impairment of DA-ergic cells in the retina, similar to the destruction of retinal cells found in PD patients. Rotenone (2.5mg/kg i.p., daily) was administered over 60 days. Neurochemically, rotenone treated rats showed a depletion of DA in the striatum and substantia nigra (SN). In addition, the number of retinal DA-ergic amacrine cells was significantly reduced in the rotenone treated animals. This study is the first one giving highlight towards a deeper understanding of systemic complex I inhibition (rotenone as an environmental toxin) and the connection between both, DA-ergic degeneration in the nigrostriatal pathway, and in the DA-ergic amacrine cells of the retina

Onset and time course of apoptosis in the developing zebrafish retina

In mammalian development, apoptosis spreads over the retina in consecutive waves and induces a remarkable amount of cell loss. No evidence for such consecutive waves has been revealed in the fish retina so far. As the zebrafish is of growing importance as a model for retinal development and for degenerative retinal diseases, we examined the onset and time course of apoptosis in the developing zebrafish retina and in adult fish. We found that apoptosis peaked in the ganglion cell layer (GCL) and inner nuclear layer (INL) in early developmental stages (3-4 days post-fertilization; dpf) followed by a second, but clearly smaller wave at 6-7dpf. Apoptosis in the outer nuclear layer (ONL) started at 5dpf and peaked at 7dpf. This late-onset high peak of apoptosis of photoreceptors is different from that of all other species examined to date. With 1.09% of cells in the GCL and 1.10% in the ONL being apoptotic, the rate of apoptosis in the developing zebrafish retina was conspicuously lower than that observed in other vertebrates (up to 50% in GCL). During development (2-21dpf), apoptotic waves were most obvious in the central retina, whereas in the periphery near the marginal zone (MZ), apoptosis was much lower; in adult animals, practically no apoptosis was present in the central retina but it still occurred near the MZ. Our data show that the onset and time course of apoptosis in the GCL and INL of the zebrafish is comparable with other vertebrates; however, the amount of apoptosis is clearly reduced. Thus, apoptosis in the zebrafish retina may serve more as a mechanism for the fine tuning of the retinal neuronal network after mitotic waves during development or in remaining mitotic areas than as a mechanism for eliminating large numbers of excess cells

Onset and time course of apoptosis in the developing zebrafish retina.

In mammalian development, apoptosis spreads over the retina in consecutive waves and induces a remarkable amount of cell loss. No evidence for such consecutive waves has been revealed in the fish retina so far. As the zebrafish is of growing importance as a model for retinal development and for degenerative retinal diseases, we examined the onset and time course of apoptosis in the developing zebrafish retina and in adult fish. We found that apoptosis peaked in the ganglion cell layer (GCL) and inner nuclear layer (INL) in early developmental stages (3-4 days post-fertilization; dpf) followed by a second, but clearly smaller wave at 6-7dpf. Apoptosis in the outer nuclear layer (ONL) started at 5dpf and peaked at 7dpf. This late-onset high peak of apoptosis of photoreceptors is different from that of all other species examined to date. With 1.09% of cells in the GCL and 1.10% in the ONL being apoptotic, the rate of apoptosis in the developing zebrafish retina was conspicuously lower than that observed in other vertebrates (up to 50% in GCL). During development (2-21dpf), apoptotic waves were most obvious in the central retina, whereas in the periphery near the marginal zone (MZ), apoptosis was much lower; in adult animals, practically no apoptosis was present in the central retina but it still occurred near the MZ. Our data show that the onset and time course of apoptosis in the GCL and INL of the zebrafish is comparable with other vertebrates; however, the amount of apoptosis is clearly reduced. Thus, apoptosis in the zebrafish retina may serve more as a mechanism for the fine tuning of the retinal neuronal network after mitotic waves during development or in remaining mitotic areas than as a mechanism for eliminating large numbers of excess cells

Impaired retinal differentiation and maintenance in zebrafish laminin mutants

PURPOSE: To characterize morphologic and physiological alterations in the retina of three laminin mutant zebrafish, bashful (bal, lama1), grumpy (gup, lamb1), and sleepy (sly, lamc1), which were identified in forward genetic screens and were found to be impaired in visual functions. METHODS: Mutant larvae were observed for defects in visual behavior by testing their optokinetic response (OKR). In addition, electroretinograms (ERG) were measured and retinal morphology was examined by standard histology, immunocytochemistry, TUNEL assay, and electron microscopy. RESULTS: Both, gup and sly showed no OKR at any light intensity tested, whereas bal embryos showed some remaining OKR behavior at more than 40% of contrast. Consistent with the OKR result, gup and sly did not show an ERG response at any light intensity tested, whereas bal mutants exhibited small a- and b-waves at high light intensities. All three laminin mutants showed altered ganglion cell layers, optic nerve fasciculations, and lens defects. Again, bal showed the least severe morphologic phenotype with no additional defects. In contrast, both, gup and sly, showed severe photoreceptor outer segment shortening and synapse alteration (floating ribbons) as well as increased cell death. CONCLUSIONS: Lamb1 and lamc1 chains play an important role in the morphogenesis of photoreceptors and their synapses. In contrast, lama1 is not involved in outer retina development